Radio frequency amplifier



April 25, 1961 H. SCHARLA-NIELSEN ETAL 2,981,896

' RADIO FREQUENCY AMPLIFIER Original Filed Sept. 12, 1957 TEFLON 7 OUTPUT ONE WALL. OF CHASSIS BIAS OTHER WALL OF CHASSIS IN VEN TORS HANS SCHARLA-NIELSEN FLOYD DONALD J. Mc LAMB BI DANIEL D. Mc RAE A TTORNE YS United States PatentO 2,981,896 RADIO FREQUENCY AMPLIFIER Original application Sept. 12, 1957, Ser. No. 683,574,

now Patent No. 2,925,477, dated Feb. 16, 1960. Divided and this application, Apr. 1, 1959, Ser. No. 808,351

7 Claims. (Cl. 330-53) This application is adiv-ision of our application Serial No. 683,574, filed September 12,.1957, now Patent No. 2,925,477,-granted February 16, 19602 a The present invention relates generally to vacuum tube amplifiers, and particularly to ultra-high frequency amplifiers having novel input and output tank configurations and coupling elements.

A variety of amplifiers are known to the prior 'art which are capable of operating in the U.H.F. region, and specifically in the vicinity of 200 mc. In general, such amplifiers have been relatively bulky devices, of lowefficiency, incapable of operation o'ver-a wide variety of environmental-conditions, having relatively small output power, and; small power gain.

It is a broad object of the present invention to provide a novel amplifier, tunable over arange of frequencies in the U;H.F. band, capable of operation from a driver of convenient impedance, and of relatively low power and voltage output, which shall have highpower gain and efliciency, be small, ruggedized, and capable of operation under severe environmental conditions.

. In'one specific embodiment of an amplifier according to the'presfent invention, 50 watts of outputpower is delivered-by a single tube to a 50 ohm load, when driven from :a two watt, 50 ohm, R;F-. oscillator or transmitter. The amplifier is readilytunable over a frequency range 215 to245'mc. l

The tube type employed is a 4CX30OA Eimac stackedceramic tetrode, which possesses the required environmental qua1ifications,-but has the; defect that tube and driving fsignal available is 10 v. R.M.S., iie.,,2 watts out ofa;50 ohm driver. :Since farmore than) V. of driving signal, is requiredfor Class C operation, it is necessary to employ voltage stepup in the input circuit. It is one high input capacitance, at highlevel; from a low level signal source; i

. -,':A further pr oblennencountered in the pertinent; is

socket have on inputeapacitance of. 40 if. To operate efiici'ently, Class C operation is employed, but, total to. designanjoutput tank forian amplifier withaQsuificiently high Q to rea-lize' a high power gain, of the order of 25,-;which is yet capable of eflicieutly coupling-about i '50'watts of; power to a 50-ohm load, the circuitry tobe, rugged and to begtuna'blevover thede'si'redifrequeney range.- It is a further feature of the invention-to provide .1

th e-requiredoutput circuitry and construction, ,1

. An input tank circuit, according to'theipresent invention consists of two transmission lines, arranged so thattheir series combination as seen; from the grid of the amplifier time, is the onju ate o t e-inp mpedance-Qt the tube, f

t the circuit resonates: One of-wthe' transmission The: othertransmissionline is; formed" tifone conductor The one line is shorter than n/4)\, where 7\ is wave length and n is odd, and hence appears as an inductance. The other line length is selected to appear as a capacitance between one side of the one line and the chassis. Across this capacitance is connected a variable trimmer condenser. v The values of capacity and inductance are selected to resonate with the tube input oapicity, and the tapping point for the one line is so selected that voltage step-up occurs.

structurally, the input tank may consist of a U-shaped metallic device, having one longer leg and one shorter leg. The base of the U provides a short at the cold end of the tank circuit, and the open end of the long leg is connected to the grid of the amplifier. The short leg is extended parallel to and is spaced from the chassis by a strip of insulation. The structure is rigid by virtue of the intimate relation between the short leg and the chassis, and may be rugged by virtue of fabrication from a solid block of metal, in which a longitudinal slot is milled.

Since the bar may be bolted solidly to the chassis while remaining electrically or conductively isolated therefrom, the structure is well suited to withstand shock and vibration, while the capacity of the bar to chassis forms a capacity which assists in tuning the input tank.

The major impedance determining element of the tank, i.e., the line formed by the long and shortleg's, may be made to have a very high Q, since the bar has extremely low resistance. The loading effects of the tuning capacitor and the grid bias circuitry appear across thelower line, i.e., the line formed by the shorter leg and the chassis, and hence do not affect the Q, and therefore the 1 voltage step up of the main or upper line.

The output tank circuit is a tuned transmission line, consisting of a metallic tube, extending parallel with the chassis of the systemand a short distance therefrom, so

as to form therewith a capacitively loaded A wave line. The chassis is more extensive or of greater length in ,the

interiorly of 'the output tank tube. Thereby the lead and I tube constitute an eifective choke for RF. R.F. choke action occurs in the sense that the anode sees a high intpedance in looking back into, the lead and tube, because the electrical length of the lead and tube considered as a transmission line is approximately one quarter wave lengtlrat the operating frequency and because the line is shorted for RF. at the end remote from the anode; Since the output tank tube may be at D.C. ground potential, output power may be derived by a tap to the tube at a point selected to provide suitable output impedance. The output tank tube may lie-shunted by avariable tuning capacitor, connected betweenthe' anode coupling capacitor and thechass'is'. This tuning capacitor is'not subjected to D.C. voltage, and hence need have only suflicient rating 'to withstand the RAF. voltage to the ,output'tank. It is, accordingly, a broad objeotof the present invention to provide a novel radio frequency amplifier, haying power gainand high 'efi'iciency', of" convenient input .open at; the-grid end and'sho'rtedatftlieg-remaining r'e'nd,w1*and' is driven' at aflpoint'adjacent the shorted 'end.

;1mp edance,and capable of driving'f'an output load of con- "venient impedance, a

It is a further object of theiinveiition tofprovide novel -vacuuin tube amplifier having a tuned transmission-line 1 7 input itank and a timed transmission line output 'tank,,th e' input tank'resonating'with the input capacity of thevacuum'tube and the, output tank being employed to provide -R.F.*powerat'z ero D.C. level, arid as an isolating element nected tov the chassis.

Still another object of the invention resides in the provision of a novel input tank circuit for an amplifier, capable of withstanding shock and vibration, and including a high Q element and a capacitive element in a unitary structure.

It is still another object of the invention to provide an output tank circuit, having a novel coupling arrangement to a vacuumtube anode, and provision for supplying D.C. voltage to the anode, the tank circuit including a metallic tube within which extends a D.C. power lead, said lead being bypassed at both ends to said tube such that it represents an RF. choke to shunt feed D.C. to the vacuum tube anode.

The above and still further objects, features and advantages of the present invention will become apparent upon consideration of the following detailed description of one specific embodiment thereof, especially when taken in conjunction with the accompanying drawings, wherein:

The single figure of the drawings is a representation, partly schematic and partly structural of an amplifier according to the present invention.

Referring now more particularly to the accompanying drawings, the reference letter T denotes a tetrode vacuum tube, preferably of the 4CX300A Eimac stacked-ceramic type, although other tube types may be employed within the scope of the invention. The tetrode T includes a cathode 1, a control grid 2, a screen grid 3 and anode 4 and a heat radiator 5, which is of metallic structure and is secured electrically and physically at multiple points about the anode 5, the anode and the radiator being cylindrical in shape.

Surrounding the radiator 5 is a layer 7 of Teflon or the like, which constitutes a suitable low loss insulating medium for a clamp 8, in the form of a ring surrounding the radiator 5 and insulated therefrom for D.C. The radiator 5, the layer of Teflon or the like 7, and the clamp 8 form a capacitorfor coupling an external tank circuit to the anode 4.

The numeral 10 denotes the chassis of an amplifier structure. Extending adjacent and parallel thereto is a metallic tube 11, the length of which, in relation to its spacing from chassis 1t} established a parallel resonant circuit, in the form of a capacitively loaded quarter wave transmission line shorted at one end. The chassis is greater in length than the transmission line itself, as is usual for a chassis and as is obvious from the drawings.

An anode power lead 12 extends internally of the tube 11, from a power terminal 13 to anode 5, in insulated relation to the tube 11. The latter is connected at 'one :end to the clamp 8, by a short lead L, and is thereby capacitively coupled to the anode' 4. The terminal 13 may be by-passed to ground for RF. by a fixed condenser 14, and the tube 11 may be shunted to ground by a variable tuning capacitor 15, which serves to vary the resonant frequency of the output tank circuit over a small range of values.

Since the tube 11 is D.C. isolatedfrom the anode, the

tuning capacitor 15 need only be designed for Withstanding R.F. voltage, and not R.F. superposed on D.C. The lead 12 in conjunction with the tube 11 provide a concentric line R.F. shorted at both ends.

Output power referenced to the chassis potential may be derived from the outside of tube 11, by means of a tap 16, and a conductive lead, since tube 11 is D.C. con- Moreover, the tap point may be selected to provide an impedance match to a 50 ohm or otherdesired load, since the tube 11 and the tap 16 act as an'impedance step-down transformer, whilethe tube itself is seen from the tube anode as a high impedance equivalent. to apara-llel resonant circuit. H

The tube 11 maybe bent into semi-circular, or circular or otherwise as desired, to conserve space. p The input'tank circuit'consists of a U-shaped bar 20,

which maybe machined from a solid block of metal. The U-shaped bar 20 includesa relatively long leg' 21, 'a

-anode voltage'in response to a signal.

relatively short leg 22 extending parallel to the long leg 21, and a base 23 joining the legs at an end. The bar then constitutes a parallel conductor transmission line open at one end, and shorted by the base 23 at the other end. 7 a

The open end 24 of the long leg 21 is directly connected to the grid 2, while a point 25 of the long leg 21, adjacent to but not at the base 23, is coupled by a capacitor 26 to a signal input terminal 27.

The short leg 22 is firmly secured to the chassis 10 mechanically, extending parallel thereto, but is electrically insulated therefrom by a layer 28 of Teflon, or other low loss insulating'material. The lower leg 22 taken.with the chassis provides then, a capacity, by virtue of its length and its spacing from the chassis. Present is both fixed capacity and capacity by virtue of transmission line properties of the leg and chassis. More over, a tunable capacity 30 isc onnected between base 23 and chassis 10, to premit variation of the effective capacity of the short leg to chassis circuit.

The input circuit of the vacuum tube possesses inherent capacity. For the preferred tube type this value is about 40,!L/Lf. The overall lengths of the input tank lines, i.e., legs 21 and 22, and their spacings and characteristic impedances, are selected to resonate with the tube input capacity, the leg 21 being for this purpose shorter than AA, where )t is the operating wave length, and hence appearing as an effective inductance.

The transmission line 20 represents an extremely high Q circuit, because fabricated of thick low resistivity metal, and because lacking in loading of any type. It follows that a tremendous gain in RF. voltage appears, as between tap 25 and grid 2. It has been found, in practice, that two watts can be supplied from a 50 ohm source, at terminal 27, and that this power is suificient to develop adequate R.F. driving voltage at the grid of the amplifier despite the fact that the amplifier is operating Class C, or nearly Class C, in order to obtain highefliciency of power conversion on the output circuit. In effect the control grid of the tetrode 1 sees an impedance conjugate to its own impedance, when looking into the line 20, and hence forms part of a series resonant network, which permits high R.F. driving current to flow. At the same time the input terminal 27 sees 50 ohms by virtue of the tap point 25, and the line 20 provides a high voltage at the grid because it is open at the grid end and is a high Q line. An impedance match exists both between the driving source and the tank circuit, and between the tank circuit and the tube input circuit, accordingly,- accompanied by a voltage step-up at the tube input circuit. Fixed bias for the control grid is provided from a negative voltage terminal 40, which is connected via choke 41, and two series connected resistances 42, 43 to the base 23. In addition, a parallel resistance 45 and condenser 46 is connected from the junction of resistance 42, 43 to ground. The latter element provides grid-leak bias, and is suitably designed for that purpose. The fixed bias may be removed when the amplifier is in operation, but is required while anode and screen voltages are applied without concurrent application of RF. drive voltage.

The-screen grid 3 is connected directly to a 13+ voltage terminal 47,; and is by-passed .to ground by a condenser 48, which in a preferred embodiment of the invention "may be built into the socket of the tube 1.

The two transmission line tank circuits, i.e., the input tank and the output tank, may be physically located on opposite sides of a chassis Wall, to reduce coupling thcr between. 7 g p Whilethe system of theinvention has been disclosed as' an amplifier, the structure and circuitry are equally adapted to utilization as an oscillator, by coupling the output leadlto the input lead in proper phase, and may .be employed as a modulated amplifier,.as by varyingthe While we have described and illustrated one specific embodiment of-our invention; it will: be: elear that. van. ations of the details of construction which are-specifically illustrated and described may be resorted to without departing from the true spirit and scope-of the invention as defined inttlie'a'iappended claims.

What-is claimed is: v I

1 rn'comlsinaadnrtank 'cii'cuitfor a power amplifying element biasdfor'cl'ass C'operation and operative at a frequency rand'a' ciir'r'espondingwave length A; said tank circuit comp" g an inductance of value L' and a capacitance of'value'cic'drinct'ed in shunt to said inductance, he e f. equ l V2.1 \./LC i pacitan being lumped, said" inductance including atwo ended; hollow tubular conductor open at both ends, a chassis comprisinggan extensivenflat ,nietallicplate, said tubular conductor' being spaced ,from said. metallic plate. over its entirelength, saidutubularrconductor having a length approximately A14 and said plate having a length substantially greater than A/ 4 in adirectionparalleLtosaid tubular conductor, only a single lead extending in insulated relation'eiitirely through. said tubular conductor and extending frombothuopen ends, a by-pass. capacitor for frequency! f couplin g said lead at only that. one of its ends immediately adjacent said tubular conductor to said metallic plate said tubular conductor and said single leadbei ng an effective choke at said frequency f, a dir'ect current connection of'negligible 'iinpedance short .circuiting the one end. of said tubular conductor corraponding with the one end of said lead to said metallic plate, said capacitance having said value C coupling the other end of said tubular conductor to said metallic plate, said amplifying element having an output electrode, the other end of said lead being connected for direct current directly to said output electrode and serving as a direct current power lead for said output electrode, and a two electrode coupling condenser coupling the other end of said tubular conductor to said output electrode, said output electrode being surrounded by one electrode of said coupling condenser and directly connected thereto at at least multiple points, the second electrode of said coupling condenser surrounding the one electrode and being insulated therefrom.

2. The combination according to claim 1 wherein said amplifying element includes a cathode, means directly connecting said cathode to a ground point, a resonant drive circuit for said amplifying element, said tank circuit being located on one side of said metallic plate, said resonant drive circuit being mounted on the other side of said metallicplate and consisting of open unshielded parallel lines.

3. The combination according to claim 2 wherein said resonant drive circuit comprises a two conductor radio frequency transmission line of which the other said metallic plate is one conductor.

4.; In a vacuum tube high efficiency'power amplifier circuit arranged to amplify signals of wave length A, a vacuum tube having an anodeand a control grid, a single flat metallic sheet having two sides, a metallic tube having two open ends, said metallic tube being spaced along itsentire length from one side of said metallic sheet, said metallic tube having a length of approximately t 4 and a spacing along its entire length from one side of said metallic sheet selected to establish a two conductor transmission.linehavingtinductive,reactance atsaidwave length-A, said"metallic sheethaving alengthgsubstant'ially greater thanthe length of-said r'netalli'c tube' in the direction of the -latter, s aid transmission line consisting of the '1 J "exterior of said" metallic tube asoue-conductor andsaid one side ofysaid gme'tallic sheet a t eta i til 7 he oth'er conductor; smission ne, atwoplatefcon-f, t v V t V it sheet, an extendeduntuned' metallic: chassis, 'a holside of and said anode, a D.C. lead. connected? at one. end .to' said anode forsupplyinganode voltagezto, said anode, said D.C. lead extending only parallel to the axis of said metallic tube interiorly of said metallic tube and through the open. ends thereof and in insulated relation thereto, means capacitively coupling said D.C. lead to said metallic tube and to said metallic sheet at the other end of said metallic tube to. provide an elfective RF. choke as seen from said anode, said effective R.F. chokecomprisi'ng'said lead and the interior wall of said metallic tube; a tuning capacitance connected between said one end of said vmetallic tube and said metallic sheet, said tuning capacitance parallel resonatingwith said resonant transmission line at said wave length A, means for'providing signal of wave length A to said control grid', and an output'lead connected to an exteriorjpoint of said metallic tube, wherein said vacuum tube includes acathode directly connected via a path of negligible {impedance to aground point, said vacuuni' tube and said metallic tube being located on the same side of said metallic sheet, said means for providing signal of wavelength A to said control grid being a resonant drive circuit forsaid'control grid, said resonant drive circuit including 'a'transmis sion line; said transmissionline including the opposite side; of said metallic sheet as a transmission line element of said transmission line,"said anode being cylindrical, said two plate condenser I connected between .one end of saidmetallic tubeand said anode including a met'allic cylinder surrounding said anode and connected to said one end of said metallic tube and an insulating cylindrical spacer extending between said metallic cylinder and said anode.

5. In combination, a power amplifier operative in class C mode at a wave length A, including a vacuum tube having an anode, a two conductor transmission line having an elfective length approximately where n is an odd integer, such that said transmission line is an inductance at said wave length A, said transmission line including as one of its conductors a hollow metallic tube open at both ends and of length approximately only a single lead extending internally of said metallic conductor and therethrough and insulated therefrom along its entire length, said lead being connected for direct current only to said anode at one end and to a B terminal at the other end, means independent of said lead solely capacitively coupling one end of said hollow metallic tube to said anode, means shorting said two conductor transmission line at its other end for D.C., means shorting said other end of said lead to the other conductor of said two conductor transmission line only for alternating current to provide an efiective radio frequency choke as seen from said anode for said wave length A, and a tuning capacitor parallel resonating with said inductance at said wave lengthA, wherein the other conductor of said transmission line is one extensive ground tube to said anode includes a metallic cylinder surrounding. said anode andinsulated therefrom.

7. Inna power amplifier for operation in class C'mode class C operation'and havingfananodesaid anode being cylindrical, a flexible insulating sheet 'surrounding ;-said Lanod'e, anda metallic cylindrical clamp surroundingand i clamping said sheet and insulated from said anodefl by at an ultra 'high frequency fi a vacuum tube biased for 7 low metallic tube having afir'stopenend and a'second open end and'a length of approximatelyu v 4 where x is thewavelength corresponding with frequency f, said hollow metallic tube extending parallel to said chassis but spaced therefrom to form a transmission line therewith, said chassis having ,a substantially greater lengthin the direction of said hollow metallic tube,'a direct connection from said first end of said hollow metallic tube to said cylindrical clamp, a direct current connection of negligibleimpedance from said second end of I said hollow metallic tube to'said chassis, an output tap connected to an external point of said hollow metallic tube intermediate said first-and second ends, a tuning condenser connected between said first end of said hollow metallic tube and said metallic chassis, said condenser having a capacitance so related to the inductance of said transmission line as to providetherewithv a tank circuit parallel resonant at the frequency f, wherein is provided a leadextending completely through said hollow metallic tube, means directly connecting one end of said lead to said, anode, means coupling the other end of said lead to said second end of said hollow metallic tube via a connection essentially consisting of condenser of negligible impedance at frequency f, and a B terminal connected to said other end of said lead, said hollow metallic tube andsaid lead constituting an effective choke at said frequency f.; y I a I '9 Reiere icesiLCitedin-the'file of this patent UNITED STATES PATENTS i 2,068,990 Kolster et al. Jan. 26,1937 2,132,208 Dunmore Oct. 4, 1938 2,143,671 Zottu Jan. 10, 1939 2,228,126 Rambo Jan. 7, 1941 2,272,062 George Feb. 3, 1942 2,416,827 George Man-4,1947 2,421,784 1 Haeseler'et al. June 10, 1947 2,463,724 Starner Mar. 8, 1949 2,748,286 Bussard May 29, 1956 "2,771,516 Bucksbaurn' -Nov. 20, 1956 2,772,355 Deutsch et a1. Nov. 27, 1956 2,774,812 Clark j Dec. 18, 1956 2,817,719 Decker... Dec. 24, 1957 2,834,948 Pan et al. May 13, 1958 OTHER REFERENCES Barrett; I.R.E. Transaction on Microwave Theory and Techniques, Vol. MIT-.3, N0. 2, March 1955, pages 1, 2 and 6.

Arditi: I.R'.E. Transactions on Microwave Theory and Techniques, Vol. MIT-3', No. 2, March 1955, pages 31 and 38. 

